Fast spin-valley-based quantum gates in Si with micromagnets

Huang, Peihao; Hu, Xuedong

doi:10.1038/s41534-021-00500-4

Cited by 9 publications

(4 citation statements)

References 89 publications

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“…It is worth noting that measurement further on the hotspot is prevented by fast relaxation during readout. This increase of EDSR Rabi frequency at the hotspot is related to the presence of a second drive mechanism which involves the presence of valley mixing in the silicon QD combined with synthetic SOC 35 . More precisely, the microwave electric field allows a transition from two different valleys but same spin ( v À ; # j i and v þ ; # j i) and the synthetic SOC couples the two opposite spins in different valleys ( v À ; " j i and v þ ; # j i) which eventually leads to an opposite spin and same valley transition ( v À ; " j i to v À ; # j i) 36 .…”

Section: Valley Enhanced Edsrmentioning

confidence: 98%

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Electrical manipulation of a single electron spin in CMOS using a micromagnet and spin-valley coupling

Klemt,

Elhomsy,

Nurizzo

et al. 2023

npj Quantum Inf

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For semiconductor spin qubits, complementary-metal-oxide-semiconductor (CMOS) technology is a promising candidate for reliable and scalable fabrication. Making the direct leap from academic fabrication to qubits fully fabricated by industrial CMOS standards is difficult without intermediate solutions. With a flexible back-end-of-line (BEOL), functionalities such as micromagnets or superconducting circuits can be added in a post-CMOS process to study the physics of these devices or achieve proofs-of-concept. Once the process is established, it can be incorporated in the foundry-compatible process flow. Here, we study a single electron spin qubit in a CMOS device with a micromagnet integrated in the flexible BEOL. We exploit the synthetic spin orbit coupling (SOC) to control the qubit via electric fields and we investigate the spin-valley physics in the presence of SOC where we show an enhancement of the Rabi frequency at the spin-valley hotspot. Finally, we probe the high frequency noise in the system using dynamical decoupling pulse sequences and demonstrate that charge noise dominates the qubit decoherence in this range.

show abstract

Section: Valley Enhanced Edsrmentioning

confidence: 98%

“…Though, we do not observe a clear enhancement of the quality factor as was proposed in ref. 35 . We therefore need to understand further the noise spectrum of the qubit and in particular the influence of charge noise.…”

Section: Valley Enhanced Edsrmentioning

confidence: 99%

Electrical manipulation of a single electron spin in CMOS using a micromagnet and spin-valley coupling

Klemt,

Elhomsy,

Nurizzo

et al. 2023

npj Quantum Inf

View full text Add to dashboard Cite

show abstract

“…It is worth noting that measurement further on the hotspot is prevented by fast relaxation during readout. This increase of EDSR Rabi frequency at the hotspot is related to the presence of a second drive mechanism which involves the presence of valley mixing in the silicon QD combined with synthetic SOC [28]. More precisely, the microwave electric field allows a transition from two different valleys but same spin (|v -, ↓ and |v + , ↓ ) and the synthetic SOC couples the two opposite spins in different valleys (|v -, ↑ and |v + , ↓ ) which eventually leads to an opposite spins and same valley transition (|v -, ↑ to |v -, ↓ ) [33].…”

Section: Valley Enhanced Edsrmentioning

confidence: 99%

“…Though, we do not observe a clear sweetspot in quality factor as was proposed in ref. [28]. We therefore need to understand further the noise spectrum of the qubit and in particular the influence of charge noise.…”

Section: Valley Enhanced Edsrmentioning

confidence: 99%

Electrical manipulation of a single electron spin in CMOS with micromagnet and spin-valley coupling

Klemt¹,

El-Homsy²,

Nurizzo³

et al. 2023

Preprint

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For semiconductor spin qubits, complementary-metal-oxide-semiconductor (CMOS) technology is the ideal candidate for reliable and scalable fabrication. Making the direct leap from academic fabrication to qubits fabricated fully by industrial CMOS standards is difficult without intermediate solutions. With a flexible back-end-of-line (BEOL) new functionalities such as micromagnets or superconducting circuits can be added in a post-CMOS process to study the physics of these devices or achieve proof of concepts. Once the process is established it can be incorporated in the foundrycompatible process flow. Here, we study a single electron spin qubit in a CMOS device with a micromagnet integrated in the flexible BEOL. We exploit the synthetic spin orbit coupling (SOC) to control the qubit via electric field and we investigate the spin-valley physics in the presence of SOC where we show an enhancement of the Rabi frequency at the spin-valley hotspot. Finally, we probe the high frequency noise in the system using dynamical decoupling pulse sequences and demonstrate that charge noise dominates the qubit decoherence in this range.

show abstract